Robot Drive with Isolated Optical Encoder

ABSTRACT

An apparatus including a frame, an optical sensor connected to the frame, and an environment separation barrier. The frame is configured to be attached to a housing of a motor assembly proximate an aperture which extends through the housing. The optical sensor comprises a camera. The environment separation barrier is configured to be connected to the housing at the aperture, where the environment separation barrier is at least partially transparent and located relative to the camera to allow the camera to view an image inside the housing through the environment separation barrier and the aperture.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.17/232,245 filed Apr. 16, 2021 which is a divisional application of U.S.application Ser. No. 16/593,050 filed Oct. 4, 2019, which is adivisional application of U.S. application Ser. No. 15/465,101 filedMar. 21, 2017, now U.S. Pat. No. 10,476,354, which claims priority under35 USC 119(e) to U.S. provisional patent application No. 62/310,989filed Mar. 21, 2016 which is hereby incorporated by reference in itsentirety, and is a continuation-in-part of U.S. patent application Ser.No. 13/744,900 filed Jan. 18, 2013 which is a divisional patentapplication of application Ser. No. 13/618,315 filed Sep. 14, 2012,which claims priority under 35 USC 119(e) on Provisional PatentApplication No. 61/627,030 filed Sep. 16, 2011 and Provisional PatentApplication No. 61/683,297 filed Aug. 15, 2012, which are herebyincorporated by reference in their entireties.

BACKGROUND Technical Field

The exemplary and non-limiting embodiments relate generally to positionsensing and, more particularly, to a robot drive position sensor havingan optical encoder.

Brief Description of Prior Developments

U.S. patent publication Nos. 2009/0243413 A1 and 2015/0303764 A1, whichare hereby incorporated by reference in their entireties, disclose abarrier between a non-optical encoder read-head and an encoder disk.

SUMMARY

The following summary is merely intended to be exemplary. The summary isnot intended to limit the scope of the claims.

In accordance with one aspect, an example embodiment is provided in anapparatus comprising a frame, where the frame is configured to beattached to a housing of a motor assembly proximate an aperture whichextends through the housing; an optical sensor connected to the frame,where the optical sensor comprises a camera; and an environmentseparation barrier configured to be connected to the housing at theaperture, where the environment separation barrier is at least partiallytransparent and located relative to the camera to allow the camera toview an image inside the housing through the environment separationbarrier and the aperture.

In accordance with another aspect, an example method comprises providinga read-head comprising a frame and a camera connected to the frame;connecting the read-head to a housing of a motor assembly, where theframe of the read-head is connected to the housing proximate an aperturewhich extends through the housing; and locating an environmentseparation barrier at the aperture to separate a first environmentalarea inside the housing from a second environmental area in which thecamera is located, where the environment separation barrier is at leastpartially transparent and located relative to the camera to allow thecamera to view an image inside the housing through the environmentseparation barrier and the aperture.

In accordance with another aspect, an example method comprisesilluminating a reference member located inside a housing of a motorassembly by a light emitter of a read-head, where the read-head islocated at least partially outside of the housing; viewing an image ofthe reference member by a camera of the read-head, where the camera islocated at least partially outside of the housing, where the image isviewed by the camera though an aperture in the housing and through atransparent environment separation barrier located at the aperture,where the transparent environment separation barrier seals a firstenvironment inside the housing from a second environment in which thesensor is located, and where the camera is located outside of the firstenvironment and the transparent environment separation barrier allowsthe camera to view the image coming from inside the housing while thecamera is outside of the first environment.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and other features are explained in the followingdescription, taken in connection with the accompanying drawings,wherein:

FIG. 1 is a schematic view of a substrate processing apparatus;

FIG. 2 is a diagram illustrating some of the components of the apparatusshown in FIG. 1 ;

FIG. 3 is a schematic diagram illustrating some of the components shownin FIGS. 1-2 ;

FIG. 3A is a diagram illustrating another example embodiment of thecomponents shown in FIGS. 1-2 ;

FIG. 4 is a schematic diagram illustrating some of the components shownin FIG. 3 ;

FIG. 4A is a schematic diagram illustrating an example of the read-headshown in FIG. 4 ;

FIG. 4B is a schematic diagram illustrating an example of multiple onesof the read-head shown in FIG. 4 ;

FIG. 5 is a diagram illustrating an example type of connectionarrangement in the sensor shown in FIGS. 3-4 ;

FIG. 6 is a diagram illustrating an example type of connection of thesensor to the housing shown in FIGS. 3-4 ;

FIG. 7 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 8 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 9 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 10 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 11 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 12 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 13 is a diagram similar to FIG. 4 showing another exampleembodiment;

FIG. 14 is a diagram similar to FIG. 4 showing another exampleembodiment; and

FIG. 15 is a diagram similar to FIG. 4 showing another exampleembodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

Referring to FIG. 1 , there is shown a schematic top plan view of anexample substrate processing apparatus 10 having a substrate transportapparatus 12. Although the present invention will be described withreference to the embodiments shown in the drawings, it should beunderstood that the present invention may be embodied in many forms ofalternative embodiments. In addition, any suitable size, shape or typeof materials or elements could be used.

In addition to the substrate transport apparatus 12, the substrateprocessing apparatus 10 includes multiple substrate processing chambers14 and substrate cassette elevators 16 connected to a vacuum chamber 15.The transport apparatus 12 is located, at least partially, in thechamber 15 and is adapted to transport planar substrates, such assemiconductor wafers or flat panel displays, between and/or among thechambers 14 and elevators 16. In alternate embodiments, the transportapparatus 12 could be used in any suitable type of substrate processingapparatus.

A conventional vacuum environment robotic manipulator typically includesa drive unit which houses all active components of the roboticmanipulator, e.g., actuators and sensors, and one or more arms, asdiscussed above, driven by the drive unit. The arm(s) are typicallypassive mechanisms, i.e., they do not include any active components,such as actuators and sensors. This is primarily due to difficultieswith out-gassing, power distribution and heat removal in vacuumenvironments.

Referring also to FIG. 2 , the substrate transport apparatus 12 (orvacuum-compatible robot system) includes a drive 18 and an arm 20. Thedrive 18 has two rotary axes. The arm 20 is coupled to the drive 18. Inthis example embodiment the arm 20 includes a first link 22, a secondlink 24 and an end-effector 26. The first link 22 is attached directlyto a first rotary axis of the drive 18. The second link 24 is coupled tothe first link 22 through a first rotary joint 28. The end-effector 26is coupled to the second link 24 through a second rotary joint 30. Inthe embodiment shown, arm 20 has three rotary axes 90, 92, 94 formed atthe drive 18 and the joints 28, 30. In this embodiment the second link24 is driven through a belt/band drive which may include a first pulley,attached to a second rotary axis of the drive 18, a first belt/band anda second pulley, attached to the second link 24 of the arm 20. Theend-effector 26 is constrained to point approximately in a radialdirection with respect to the drive 18 through another belt/bandarrangement, which may include a third pulley, pivotably coupled to thefirst link 22, a second belt/band and a fourth pulley, attached to theend-effector 26. In various different example embodiments, any suitabledrive, actuator, sensor or otherwise may provide features as disclosedherein; in any combination and/or as disclosed in U.S. Pat. No.9,202,733 and U.S. Pat. No. 8,716,909 which are all hereby incorporatedby reference in their entireties herein.

Although the substrate transport apparatus 12 is described with respectto a vacuum robot, any suitable substrate transport apparatus;atmospheric or otherwise may be provided having features as disclosed.Substrate transport apparatus 12 has a controller 54, the drive unit 18and the arm 20, and is configured to transport substrate S. Controller54 may have at least one processor 32, at least one memory 34 andsoftware or computer code 36 configured to control the drive 18 andprocess input from the sensors. Arm 20 is shown as a SCARA type arm anddriven by drive unit 18, but in alternate embodiments any suitable armcould be provided. Although substrate transport apparatus 12 isdescribed with respect to a two link arm, any suitable number of linksmay be provided. Further, any suitable number of arms may be provided.Further, any combination of rotary and/or linear axis may be provided onany suitable arm.

The drive 18 forms a robot motor assembly. In this example the robotmotor assembly comprising stators and rotors configured to drive shaftsconnected to the first link 22 and one of the pulleys in the first link.Referring also to FIG. 3 , the drive 18 comprises a housing 38 whichseparates the environmental area 40 inside the drive 18 and inside thechamber 15 from the environmental area 42 outside the drive and thechamber. A position encoder reference member or disk is connected toeach one of the rotors or shafts of the drive 18. FIG. 3 shows anexample of this where a position encoder reference member disk 44 isshown attached to the shaft/rotor 46. The housing 38 of the motorassembly has an aperture 48 therethrough. The aperture 48 is alignedwith the position encoder reference member disk 44. Attached to thehousing 38 is a position read-head 50. The position read-head 50 islocated at the aperture 48 through the housing 38 in order for theread-head 50 to sense the location or position of the position encoderreference member disk 44 as the disk 44 is rotated when the rotor/shaft46 rotates. Output from the read-head 50 is supplied to the controller54. Another example is shown in FIG. 3A which diagrammatically shows adirect-drive module of a robot, such as the example robot depicted inFIG. 1 in U.S. patent application publication No. 2014/0077637, showingthe shaft 46 a, a stator and rotor of a motor 47, a direct drive modulehousing 38 a, an encoder track or reference member 44 a, bearings 49 andan encoder sensor 60 a.

Referring also to FIG. 4 , in this embodiment the position read-head 50generally comprises a frame 56, a light emitter 58, an optical sensor60, an environment separation barrier 62 and electronic circuitry 59. Inone type of example embodiment the sensor 60 is a plurality of opticalsensors arranged as an array for viewing at least one image, and thelight emitter 58 comprises a plurality of light emitters. An example ofthis is shown in FIG. 4A with read-head 50′. In another alternative, asshown in FIG. 4B, the apparatus may comprises multiple read-heads 50″,50′″ having different light emitter and optical sensor configurations,but attached to the housing 38 to read the same reference member 44.

Referring also to FIG. 5 , in this example embodiment the firstconnection 64 is provided between the sensor 60 and the frame 56 and asecond connection 66 is provided between the separation barrier 62 andthe frame 56. However, as illustrated by FIG. 6 , the sensor 60 and theseparation barrier 62 may be a unitary assembly with the sensor framewith a single type of connection 68 to the housing 38. The connections64, 66, 68 may be stationarily fixed or adjustable. In the example shownin FIG. 4 , the connection 64 is stationarily fixed, the connection 66is a resiliently deflectable connection, and the connection 68 isadjustable.

In this example embodiment the environment separation barrier 62 is atransparent window and the optical sensor 60 is a camera. A holder 70 isprovided to hold the transparent window 62. The holder 70 is connectedby the connection 66 to the frame 56. The holder 70 is biased by theconnection 66 in the direction of the aperture 48 to press thetransparent window 62 against the seal 72. Thus, the seal 72 and thewindow 62 seal off the aperture 48 forming an optically transparentbarrier between the two environmental areas 40, 42 at the aperture 48.Because the barrier 62 is optically transparent, the camera 60 is stillable to view an image from the reference member 44. Because thecomponents of the read-head 50, including the camera 60, light emitter58 and electronic circuitry 59, are all outside the environmental area40, there is no risk of outgassing from these components inside the area40. Because the components of the read-head 50, including the camera 60,light emitter 58 and electronic circuitry 59, are all outside theenvironmental area 40, no special design or encasement of the read-head50 or its components is necessary.

With features as described herein, a position encoder may beincorporated into a robot direct-drive module, such as drive 18 or oneof a plurality of drive modules which are assembled to form the drive18. A position encoder track, such as on the disk 44, may be coupled tothe driven part 46 of the direct-drive module, and a position read-headmay be provided on the outside of the housing 38 of the direct-drivemodule, for example, as shown in the example embodiments shown in thedrawings.

In one exemplary embodiment, as depicted diagrammatically in FIG. 4 ,the housing 38 of the direct-drive module may feature an aperture (slot)48 located so that it provides an optical path (view) of the positionencoder track from the outside of the housing of the direct-drivemodule. The aperture 48 may feature a separation barrier 62 to separatethe vacuum or other non-atmospheric environment inside of the housing ofthe direct-drive module from the environment outside of the housing ofthe direct-drive module. The separation barrier 62 may be made of asubstantially transparent material, such as glass or acrylic forexample. The separation barrier 62 may be sealed to the housing of thedirect-drive module, for example, using an O-ring or a bonded joint, forexample, or in any other suitable manner.

The encoder track on the reference member 44 may include features thatmay be utilized to sense location of the encoder track. As an example,the features may form an incremental track and, in some case, theincremental track may be complemented by an absolute track. As anotherexample, the features may form a pattern that may be decoded using imageprocessing techniques.

As shown in FIG. 4 , a read-head 50 may be provided on the outside ofthe direct-drive module so that it may sense location of the encodertrack through the aperture in the housing of the direct-drive module.The read-head may be attached to the housing of the direct-drive modulein a substantially fixed manner or it may be coupled to the housing ofthe direct-drive module in a movable manner to allow for adjustment ofthe read-head with respect to the encoder track. The adjustment mayinclude the distance between the read-head and the encoder track as wellas orientation (for instance, pitch, roll and yaw) of the read-head withrespect to the encoder track. Alternatively, the read-head may be heldin the proximity of the aperture in any suitable manner.

Still referring to FIG. 4 , the read-head may include an enclosure 56and an optical system (including sensor 60). The read-head may furtherinclude other components, such as electronics, to control the read-head,process the data and facilitate communication.

The optical system may be configured to detect the position of theencoder track with respect to the read-head. As an example, the opticalsystem may include one or more light emitters, one or more lightreceiver and other optical components, such as lenses, mirrors andmasks. The light emitter(s) and receiver(s) may be arranged to detectfeatures on the encoder track. For instance, the receiver(s) may detectthe features based on reflection of the light produced by theemitter(s).

As another example, the optical system may include one or more lightsource(s), one or more digital camera(s) and other optical components,such as lenses, mirrors and masks. The light source(s) may be arrangedto provide illumination of the encoder track in the field of view of thedigital camera(s). The digital camera(s) may be arranged to takeperiodically pictures (images) of the encoder track. The pictures may beprocessed by the encoder read-head and/or externally to the encoderread-head, such as at the controller 54 for example, to determine thelocation of the encoder track with respect to the encoder read-head.

In another example embodiment, as depicted diagrammatically in FIG. 7 ,the housing 38 of the direct-drive module may feature an aperture (slot)48 located so that it provides an optical path (view) of the positionencoder track 44 from the outside of the housing of the direct-drivemodule. A read-head 50 a may be provided on the outside of thedirect-drive module so that it can sense location of the encoder track44 through the aperture in the housing of the direct-drive module.

The encoder track 44 may include features that may be utilized to senselocation of the encoder track. As an example, the features may form anincremental track and, in some case, the incremental track may becomplemented by an absolute track. As another example, the features mayform a pattern that may be decoded using image processing techniques.

The read-head 50 a may include an enclosure 56 a, a window 62 and anoptical system including 58, 60. The read-head 50 a may further includeother components, such as electronics, to control the read-head, processthe data and facilitate communication.

As depicted in FIG. 7 , the window 62 may be located in the enclosure ofthe read-head to provide an optical path (view) between the opticalsystem 58, 60 and the encoder track 44 through the aperture 48 in thehousing 38 of the direct-drive module. The window 62 may be made of asubstantially transparent material, such as glass or acrylic.

The optical system may be configured to detect the position of theencoder track 44 with respect to the read-head. As an example, theoptical system may include one or more light emitter(s), one or morelight receiver(s) and other optical components, such as lenses, mirrorsand masks. The light emitter(s) and receiver(s) may be arranged todetect features on the encoder track. For instance, the receiver(s) maydetect the features based on reflection of the light produced by theemitter(s). The light source(s) may be arranged to provide illuminationof the encoder track in the field of view of the digital camera(s). Thedigital camera(s) 60 may be arranged to take periodically pictures(images) of the encoder track. The pictures may be processed by theencoder read-head to determine the location of the encoder track withrespect to the encoder read-head.

The read-head 50 a may be attached to the housing 38 of the direct-drivemodule so that the window 62 of the read-head is sealed with respect tothe housing 38 of the direct-drive module around the aperture 48 of thedirect drive module, thus separating the vacuum or other non-atmosphericenvironment inside of the housing of the direct-drive module from theenvironment outside of the direct-drive module. As a result, thecomponents inside of the enclosure of the read-head 50 a are not exposedto the vacuum or other non-atmospheric environment inside of the housingof the direct-drive module.

As illustrated in FIG. 7 , the read-head may be attached to the housingof the direct-drive module in a substantially fixed manner, and thewindow 62 may be sealed to the housing 38 of the direct-drive moduleusing an O-ring or any other suitable seal. Additional examples of sealconfigurations are depicted diagrammatically in FIGS. 8, 9 (sealcompressed in the direction normal to the direction of the installationof the read-head) and 10 (O-ring compressed along the direction of theinstallation of the read-head). FIG. 8 shows housing 38 b with aperture48 b, and the read-head 50 b having frame 56 b, seal 72 b, window 62 band optical components including light emitter 58 and sensor 60. FIG. 9shows housing 38 c with aperture 48 c, and the read-head 50 c havingframe 56 c, seal 72 b, window 62 b and optical components includinglight emitter 58 and sensor 60. FIG. 10 shows housing 38 b with aperture48 b, and the read-head 50 d having frame 56 c, seal 72 d, window 62 dand optical components including light emitter 58 and sensor 60. Thewindow 62 may also be shaped to provide adequate space for the seal and,at the same time, allow for desirably close proximity of the componentsof the sensor to the encoder track, as illustrated in FIG. 11 . FIG. 11shows housing 38 b with aperture 48 b, and the read-head 50 e havingframe 56 c, seal 72 d, window 62 e and optical components includinglight emitter 58 and sensor 60.

It should be noted that in all of the example configurations of FIGS.7-11 the window 62 may be merely mechanically fastened, but notnecessarily sealed, with respect to the enclosure 56 of the sensor, andthe sealing takes place between the window 62 and the housing 38 of thedirect-drive module. It should be noted that the window 62 in theexamples of FIGS. 7-11 may not necessarily be a separate component. Thewindow 62 may be conveniently formed by a component of the opticalsystem of the read-head, such as a lens, or by any other suitablecomponent.

Alternatively, the read-head may be coupled to the housing of thedirect-drive module in a movable manner to allow for adjustment of thesensor with respect to the encoder track. The adjustment may include thedistance between the read-head and the encoder track as well asorientation (for instance, pitch, roll and yaw) of the read-head withrespect to the encoder track. The window of the sensor may be sealed tothe housing of the direct-drive module by an O-ring, a bellows, aflexure or any other suitable seal providing the sensor with sufficientmovement while maintaining a seal.

In yet another example embodiment, as depicted diagrammatically in FIG.12 , the housing of the direct-drive module may feature an aperture(slot) located so that it provides an optical path (view) of theposition encoder track from the outside of the housing of thedirect-drive module. A read-head may be provided on the outside of thedirect-drive module so that it can sense location of the encoder trackthrough the aperture in the housing of the direct-drive module. FIG. 12shows housing 38 with aperture 48, and the read-head 50 f having frame56 f, seal 72, window 62 f, seal 72 f and optical components includinglight emitter 58 and sensor 60.

The encoder track may include features that may be utilized to senselocation of the encoder track. As an example, the features may form anincremental track and, in some case, the incremental track may becomplemented by an absolute track. As another example, the features mayform a pattern that may be decoded using image processing techniques.

The read-head may include an enclosure, a window and an optical system.The read-head may further include other components, such as electronics,to control the read-head, process the data and facilitate communication.

As depicted in FIG. 12 , the window may be located in the enclosure ofthe read-head to provide an optical path (view) between the opticalsystem and the encoder track through the aperture in the housing of thedirect-drive module. The window may be made of a substantiallytransparent material, such as glass or acrylic. The window may be sealedto the enclosure of the sensor, for instance, using an O-ring or abonded joint.

The optical system may be configured to detect the position of theencoder track with respect to the read-head. As an example, the opticalsystem may include one or more light emitters, one or more lightreceivers and other optical components, such as lenses, mirrors andmasks. The light emitter(s) and receiver(s) may be arranged to detectfeatures on the encoder track. For instance, the receiver(s) may detectthe features based on reflection of the light produced by theemitter(s).

As another example, the optical system may include one or more lightsource(s), one or more digital camera(s) and other optical components,such as lenses, mirrors and masks. The light source(s) may be arrangedto provide illumination of the encoder track in the field of view of thedigital camera(s). The digital camera(s) may be arranged to takeperiodically pictures (images) of the encoder track. The pictures may beprocessed by the encoder read-head to determine the location of theencoder track with respect to the encoder read-head.

The read-head may be attached to the housing of the direct-drive moduleso that the enclosure of the sensor is sealed with respect to thehousing of the direct-drive module around the aperture of the directdrive module and around the window of the read-head, thus separating thevacuum or other non-atmospheric environment inside of the housing of thedirect-drive module from the environment outside of the direct-drivemodule and, furthermore, separating the components inside of theenclosure of the read-head from the vacuum or other non-atmosphericenvironment inside of the housing of the direct-drive module. Thisprevents exposure of the components inside of the enclosure of theread-head from the vacuum or other non-atmospheric environment inside ofthe housing of the direct-drive module.

As illustrated in FIG. 12 , the read-head may be attached to the housingof the direct-drive module in a substantially fixed manner, and theenclosure of the sensor may be sealed to the housing of the direct-drivemodule using an O-ring or any other suitable seal. Additional exampleembodiments where the window is sealed to the enclosure of the read-headand the enclosure of the read-head is in turn sealed to the housing ofthe direct-drive module are depicted diagrammatically in FIGS. 14-15 .FIG. 14 shows housing 38 h with aperture 48 h, and the read-head 50 hhaving frame 56 h, seals 72 h 1, 72 h 2, window 62 h and opticalcomponents including light emitter 58 and sensor 60. FIG. 15 showshousing 38 h with aperture 48 h, and the read-head 50 i having frame 56i, seals 72 h 1, 72 h 2, window 62 h and optical components includinglight emitter 58 and sensor 60.

It should be noted that the window in the example of FIG. 12 may notnecessarily be a separate component. The window may be convenientlyformed by a component of the optical system of the sensor, such as alens, or by any other suitable component.

Alternatively, the read-head may be coupled to the housing of thedirect-drive module in a movable manner to allow for adjustment of theread-head with respect to the encoder track. The adjustment may includethe distance between the read-head and the encoder track as well asorientation (for instance, pitch, roll and yaw) of the read-head withrespect to the encoder track. The enclosure of the read-head may besealed to the housing of the direct-drive module by an O-ring, abellows, a flexure or any other suitable seal providing the read-headwith sufficient movement while maintaining a seal.

In yet another example embodiment, as depicted diagrammatically in FIG.13 , the housing of the direct-drive module may feature an aperture(slot) located so that it provides an optical path (view) of theposition encoder track from the outside of the housing of thedirect-drive module. FIG. 13 shows housing 38 g with aperture 48 g, andthe read-head 50 g having frame members 56 g 1, 56 g 2, seals 72 g 1, 72g 2, window 62 g and optical components including light emitter 58 andsensor 60. A sensor may be provided on the outside of the direct-drivemodule so that it can sense location of the encoder track through theaperture in the housing of the direct-drive module.

The encoder track may include features that may be utilized to senselocation of the encoder track. As an example, the features may form anincremental track and, in some case, the incremental track may becomplemented by an absolute track. As another example, the features mayform a pattern that may be decoded using image processing techniques.

The read-head may include a first enclosure, a window and an opticalsystem. The sensor may further include other components, such aselectronics, to control the read-head, process the data and facilitatecommunication.

As depicted in FIG. 13 , the window may be located in the firstenclosure of the read-head to provide an optical path (view) between theoptical system and the encoder track through the aperture in the housingof the direct-drive module. The window may be mechanically fastened tothe first enclosure of the read-head and sealed to a second enclosure(window seal in FIG. 13 ), neither enclosure being the housing of thedirect-drive module. The second enclosure may then seal to the housingof the direct-drive module (enclosure seal in FIG. 13 ). This allows aread-head housings never intended to act as a barrier between atmosphereand non-atmosphere environments to do be utilized.

The window may be made of a substantially transparent material, such asglass or acrylic. Alternatively, as explained with respect to theexamples for FIGS. 6-12 , the window may be conveniently formed by acomponent of the optical system of the read-head, such as a lens,another optical element intended to affect light, or any other suitablecomponent.

The window may be sealed to the first enclosure of the read-head, forinstance, using an O-ring or a bonded joint. If desired, the seal may beaccomplished by the addition of a feature to the window, such as aflange. Alternatively, the seal may be accomplished by using featuresavailable on commercially available read-heads.

The optical system may be configured to detect the position of theencoder track with respect to the read-head. As an example, the opticalsystem may include one or more light emitters, one or more lightreceivers and other optical components, such as lenses, mirrors andmasks. The light emitter(s) and receiver(s) may be arranged to detectfeatures on the encoder track. For instance, the receiver(s) may detectthe features based on reflection of the light produced by theemitter(s).

As another example, the optical system may include one or more lightsource(s), one or more digital camera(s) and other optical components,such as lenses, mirrors and masks. The light source(s) may be arrangedto provide illumination of the encoder track in the field of view of thedigital camera(s). The digital camera(s) may be arranged to takeperiodically pictures (images) of the encoder track. The pictures may beprocessed by the encoder read-head to determine the location of theencoder track with respect to the encoder read-head.

The read-head may be attached to the housing of the direct-drive moduleso that the second enclosure is sealed with respect to the housing ofthe direct-drive module. The second enclosure is then sealed to thewindow of the read-head, thus separating the vacuum or othernon-atmospheric environment inside of the housing of the direct-drivemodule from the environment outside of the direct-drive module and,furthermore, separating the components inside of the second enclosurefrom the vacuum or other non-atmospheric environment inside of thehousing of the direct-drive module. This prevents exposure of thecomponents inside of the second enclosure from the vacuum or othernon-atmospheric environment inside of the housing of the direct-drivemodule.

Alternatively, the second enclosure may be coupled to the housing of thedirect-drive module in a movable manner to allow for adjustment of theread-head with respect to the encoder track. The adjustment may includethe distance between the read-head and the encoder track as well asorientation (for instance, pitch, roll and yaw) of the read-head withrespect to the encoder track. The second enclosure may be sealed to thehousing of the direct-drive module by an O-ring, a bellows, a flexure orany other suitable seal providing the read-head with sufficient movementwhile maintaining a seal.

Although the above example embodiments show the read-head lookingradially inward, it may be arranged to look radially out, for examplepointing at an internal cylindrical surface of the disk, or to lookaxially up or down, for example, pointing at one of the flat faces ofthe disk.

Features as described herein may be used to provide a drive arrangement(such as a robot drive arrangement) with an optical encoder where thedisk of the optical encoder is in one environment (such as vacuumenvironment) and the components of the read-head of the optical encoder,including its optical system and control electronics, are in anotherenvironment (such as an atmospheric environment) and there is asubstantially transparent barrier between the disk and the components ofthe read-head.

Although the example embodiments show the read-head looking radiallyinward, the sensor may be arranged to look radially out on an internalcylindrical surface of the disk, or to look axially (up or down) on oneof the flat faces of the disk 44. This arrangement may be extended tolinear applications including, for example, the example linear robotsdescribed in U.S. patent publication Nos. 2015/0214086 A1, 2016/0229296A1 and 2017/0036358 A1 which are hereby incorporated by reference intheir entireties.

An example apparatus comprises a frame, where the frame is configured tobe attached to a housing of a motor assembly proximate an aperture whichextends through the housing; a position sensor connected to the frame,where the position sensor comprises a camera; and an environmentseparation barrier configured to be connected to the housing at theaperture, where the environment separation barrier is at least partiallytransparent and located relative to the camera to allow the camera toview an image inside the housing through the environment separationbarrier and the aperture. The environment separation barrier may beconnected directly to the housing at the aperture or may be indirectlyconnected to the housing, such as via the frame of the apparatus, butthe environment separation barrier forms at least part of theenvironment closure of the aperture through the housing while alsoproviding an optical path.

The apparatus may comprise a seal configured to be located directlybetween the environment separation barrier and the housing of the motorassembly. The apparatus may comprise a first seal connected directlybetween the environment separation barrier and the frame. The apparatusmay comprise a second seal configured to be located directly between theframe and the housing of the motor assembly. The apparatus may comprisea seal and a barrier holder configured to press the environmentseparation barrier against the seal, where the barrier holder isconfigured to be pressed by the frame towards the aperture. Theapparatus may comprise a connection between the barrier holder and theframe which is resilient to allow the barrier holder to move relative tothe frame, and where the connection biases the barrier holder towardsthe aperture when the frame is connected to the housing. The environmentseparation barrier may comprise a transparent window which directlycontacts the frame and is configured to be pressed by the frame towardsthe aperture when the frame is connected to the housing. The apparatusmay comprise the housing, a rotor inside the housing having a positionreference member configured to be imaged by the camera and at least oneseal, where the frame is connected to the housing with the at least oneseal and the environment separation barrier sealing the aperture toseparate a first environmental area inside the housing from a secondenvironmental area outside the housing. The frame may not be exposed tothe first environmental area inside the housing.

An example method may comprise providing a read-head comprising a frameand a camera connected to the frame; connecting the read-head to ahousing of a motor assembly, where the frame of the read-head isconnected to the housing proximate an aperture which extends through thehousing; and locating an environment separation barrier at the apertureto separate a first environmental area inside the housing from a secondenvironmental area in which the camera is located, where the environmentseparation barrier is at least partially transparent and locatedrelative to the camera to allow the camera to view an image inside thehousing through the environment separation barrier and the aperture.

The method may comprise locating a seal being directly between theenvironment separation barrier and the housing of the motor assembly.The method may comprise connecting a first seal directly between theenvironment separation barrier and the frame. The method may compriselocating a second seal directly between the frame and the housing of themotor assembly. The method may comprise a barrier holder biasing theenvironment separation barrier against a seal, where the barrier holderis pressed by the frame towards the aperture. The method may compriseproving a connection between the barrier holder and the frame which isresilient to allow the barrier holder to move relative to the frame, andwhere the connection biases the barrier holder towards the aperture whenthe frame is connected to the housing. The environment separationbarrier may comprise a transparent window which directly contacts theframe and is pressed by the frame towards the aperture when the frame isconnected to the housing. The method may comprise a rotor is inside thehousing and a position reference member configured to be imaged by thecamera, where the frame is connected to the housing with at least oneseal and the environment separation barrier to seal the aperture toseparate a first environmental area inside the housing from a secondenvironmental area outside the housing. The frame may not be exposed tothe first environmental area inside the housing.

An example method may comprise illuminating a reference member locatedinside a housing of a motor assembly by a light emitter of a sensor,where the sensor is located outside of the housing; viewing an image ofthe reference member by a camera of the sensor, where the camera islocated outside of the housing, where the image is viewed by the camerathough an aperture in the housing and through a transparent environmentseparation barrier located at the aperture, where the transparentenvironment separation barrier seals a first environment inside thehousing from a second environment in which the sensor is located, andwhere the camera is located outside of the first environment and thetransparent environment separation barrier allows the camera to view theimage coming from inside the housing while the camera is outside of thefirst environment.

The example of FIG. 4 illustrates a viewport in the housing of thedirect-drive module. The examples of FIGS. 7-11 illustrate a sealdirectly between the window and the housing of the direct-drive module.The examples of FIGS. 12 and 14-15 illustrate a seal between the windowand the enclosure of the read-head and another seal between theenclosure of the read-head and the housing of the direct-drive module.The example of FIG. 13 illustrates two enclosures.

An example embodiment may be provided in an apparatus comprising aframe, where the frame is configured to be attached to a housing of amotor assembly proximate an aperture which extends through the housing;at least one light emitter connected to the frame; an array of opticalsensors connected to the frame; and an environment separation barrierconfigured to be connected to the housing at the aperture, where theenvironment separation barrier is at least partially transparent andlocated relative to the array of optical sensors to allow the array ofoptical sensors to view an image inside the housing through theenvironment separation barrier and the aperture.

An example method may be provided comprising providing a read-headcomprising a frame, at least one light emitter connected to the frame,and an array of optical sensors connected to the frame; connecting theread-head to a housing of a motor assembly, where the frame of theread-head is connected to the housing proximate an aperture whichextends through the housing; and locating an environment separationbarrier at the aperture to separate a first environmental area insidethe housing from a second environmental area in which the array ofoptical sensors is located, where the environment separation barrier isat least partially transparent and located relative to the array ofoptical sensors to allow the array of optical sensors to view an imageinside the housing through the environment separation barrier and theaperture.

An example method may be provided comprising illuminating a referencemember located inside a housing of a motor assembly by at least onelight emitter of a read-head, where the read-head is located At leastpartially outside of the housing; viewing at least one image of thereference member by an array of optical sensors of the read-head, wherethe array of optical sensors is located at least partially outside ofthe housing, where the at least one image is viewed by the array ofoptical sensors though an aperture in the housing and through atransparent environment separation barrier located at the aperture,where the transparent environment separation barrier seals a firstenvironment inside the housing from a second environment in which thearray of optical sensors is located, and where the array of opticalsensors is located outside of the first environment and the transparentenvironment separation barrier allows the array of optical sensors toview the at least one image coming from inside the housing while thecamera is outside of the first environment.

It should be understood that the foregoing description is onlyillustrative. Various alternatives and modifications can be devised bythose skilled in the art. For example, features recited in the variousdependent claims could be combined with each other in any suitablecombination(s). In addition, features from different embodimentsdescribed above could be selectively combined into a new embodiment.Accordingly, the description is intended to embrace all suchalternatives, modifications and variances which fall within the scope ofthe appended claims.

What is claimed is:
 1. An apparatus comprising: a frame, where the frameis configured to be attached to a housing of a motor assembly proximatean aperture which extends through the housing; at least one lightemitter connected to the frame; an array of optical sensors connected tothe frame; and an environment separation barrier configured to beconnected to the housing at the aperture, where the environmentseparation barrier is at least partially transparent and locatedrelative to the array of optical sensors to allow the array of opticalsensors to view an image inside the housing through the environmentseparation barrier and the aperture.
 2. An apparatus as in claim 1further comprising a seal configured to be located directly between theenvironment separation barrier and the housing of the motor assembly. 3.An apparatus as in claim 1 further comprising a first seal connecteddirectly between the environment separation barrier and the frame.
 4. Anapparatus as in claim 3 further comprising a second seal configured tobe located directly between the frame and the housing of the motorassembly.
 5. An apparatus as in claim 1 further comprising a seal and abarrier holder configured to press the environment separation barrieragainst the seal, where the barrier holder is configured to be pressedby the frame towards the aperture.
 6. An apparatus as in claim 5 furthercomprising a connection between the barrier holder and the frame whichis resilient to allow the barrier holder to move relative to the frame,and where the connection biases the barrier holder towards the aperturewhen the frame is connected to the housing.
 7. An apparatus as in claim1 where the environment separation barrier comprises a transparentwindow which directly contacts the frame and is configured to be pressedby the frame towards the aperture when the frame is connected to thehousing.
 8. An apparatus as in claim 1 further comprising the housing, arotor inside the housing having a position reference member configuredto be imaged by the array of optical sensors and at least one seal,where the frame is connected to the housing with the at least one sealand the environment separation barrier sealing the aperture to separatea first environmental area inside the housing from a secondenvironmental area outside the housing.
 9. An apparatus as in claim 8where the frame is not exposed to the first environmental area insidethe housing.
 10. An apparatus as in claim 1 where the array of opticalsensors comprises an array of cameras.
 11. A method comprising:providing a read-head comprising a frame, at least one light emitterconnected to the frame, and an array of optical sensors connected to theframe; connecting the read-head to a housing of a motor assembly, wherethe frame of the read-head is connected to the housing proximate anaperture which extends through the housing; and locating an environmentseparation barrier at the aperture to separate a first environmentalarea inside the housing from a second environmental area in which thearray of optical sensors is located, where the environment separationbarrier is at least partially transparent and located relative to thearray of optical sensors to allow the array of optical sensors to viewan image inside the housing through the environment separation barrierand the aperture.
 12. A method as in claim 11 further comprisinglocating a seal being directly between the environment separationbarrier and the housing of the motor assembly.
 13. A method as in claim11 further comprising connecting a first seal directly between theenvironment separation barrier and the frame.
 14. A method as in claim13 further comprising locating a second seal directly between the frameand the housing of the motor assembly.
 15. A method as in claim 11further comprising a barrier holder biasing the environment separationbarrier against a seal, where the barrier holder is pressed by the frametowards the aperture.
 16. A method as in claim 15 further comprisingproving a connection between the barrier holder and the frame which isresilient to allow the barrier holder to move relative to the frame, andwhere the connection biases the barrier holder towards the aperture whenthe frame is connected to the housing.
 17. A method as in claim 11 wherethe environment separation barrier comprises a transparent window whichdirectly contacts the frame and is pressed by the frame towards theaperture when the frame is connected to the housing.
 18. A method as inclaim 11 where a rotor is inside the housing and has a positionreference member configured to be imaged by the array of opticalsensors, where the frame is connected to the housing with at least oneseal and the environment separation barrier to seal the aperture toseparate a first environmental area inside the housing from a secondenvironmental area outside the housing.
 19. A method as in claim 18where the frame is not exposed to the first environmental area insidethe housing.
 20. A method as in claim 11 where the array of opticalsensors comprises at least one camera.